Abelian integral explained
In mathematics, an abelian integral, named after the Norwegian mathematician Niels Henrik Abel, is an integral in the complex plane of the form
where
is an arbitrary
rational function of the two variables
and
, which are related by the equation
where
is an
irreducible polynomial in
,
| n+ … +\varphi |
| F(x,w)\equiv\varphi | |
| 1(x)w |
+\varphi0\left(x\right),
whose coefficients
,
are
rational functions of
. The value of an abelian integral depends not only on the integration limits, but also on the path along which the integral is taken; it is thus a
multivalued function of
.
Abelian integrals are natural generalizations of elliptic integrals, which arise when
where
is a polynomial of degree 3 or 4. Another special case of an abelian integral is a
hyperelliptic integral, where
, in the formula above, is a polynomial of degree greater than 4.
History
The theory of abelian integrals originated with a paper by Abel[1] published in 1841. This paper was written during his stay in Paris in 1826 and presented to Augustin-Louis Cauchy in October of the same year. This theory, later fully developed by others,[2] was one of the crowning achievements of nineteenth century mathematics and has had a major impact on the development of modern mathematics. In more abstract and geometric language, it is contained in the concept of abelian variety, or more precisely in the way an algebraic curve can be mapped into abelian varieties. Abelian integrals were later connected to the prominent mathematician David Hilbert's 16th Problem, and they continue to be considered one of the foremost challenges in contemporary mathematics.
Modern view
In the theory of Riemann surfaces, an abelian integral is a function related to the indefinite integral of a differential of the first kind. Suppose we are given a Riemann surface
and on it a
differential 1-form
that is everywhere
holomorphic on
, and fix a point
on
, from which to integrate. We can regard
, or (better) an honest function of the chosen path
drawn on
from
to
. Since
will in general be
multiply connected, one should specify
, but the value will in fact only depend on the
homology class of
.
In the case of
a compact Riemann surface of
genus 1, i.e. an
elliptic curve, such functions are the
elliptic integrals. Logically speaking, therefore, an abelian integral should be a function such as
.
Such functions were first introduced to study hyperelliptic integrals, i.e., for the case where
is a
hyperelliptic curve. This is a natural step in the theory of integration to the case of integrals involving
algebraic functions
, where
is a
polynomial of degree
. The first major insights of the theory were given by Abel; it was later formulated in terms of the
Jacobian variety
. Choice of
gives rise to a standard
holomorphic function
of complex manifolds. It has the defining property that the holomorphic 1-forms on
, of which there are
g independent ones if
g is the genus of
S,
pull back to a basis for the differentials of the first kind on
S.
Notes
References
- Encyclopedia: Abel . Niels H. . Niels Henrik Abel . Mémoires présentés par divers savants à l’Académie Royale des Sciences de l’Institut de France . Mémoire sur une propriété générale d’une classe très étendue de fonctions transcendantes . French . 1841 . Paris . 176-264 .
- Book: Appell . Paul . Paul Appell . Goursat . Édouard . Édouard Goursat . Théorie des fonctions algébriques et de leurs intégrales . French . Gauthier-Villars . Paris . 1895.
- Book: Bliss . Gilbert A. . Gilbert Ames Bliss . Algebraic Functions . . Providence . 1933.
- Book: Forsyth . Andrew R. . Andrew Forsyth . Theory of Functions of a Complex Variable . . Providence . 1893.
- Book: Griffiths . Phillip . Phillip Griffiths . Harris . Joseph . Joe Harris (mathematician) . Principles of Algebraic Geometry . . New York . 1978.
- Book: Neumann . Carl . Carl Neumann . Vorlesungen über Riemann's Theorie der Abel'schen Integrale . . 2nd . Leipzig . 1884.
Notes and References
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